RU1795117C - Method for monitoring and prevention of coal and gas outburst in driving workings through coal seams - Google Patents

Abstract

The invention relates to methods for the storm of control holes for a potentially outburst pack of coal equidistant from the soil and its roof, the use of control holes at the same time for anti-blowout processing of the array and monitoring its effectiveness, in: -. ... - 2 -:; monitoring the effectiveness of the method directly in the process of drilling holes by measuring the initial gas evolution rate in the interval where the maximum value was established when drilling the first two holes. If the value of the hazard factor of the bottom-hole part of the massif is higher than the critical value in the gauge with drilled holes, a central hole is drilled at an equal distance from them, then two additional holes are drilled at the same depth, and each of them measures the initial gas release rate in the interval during drilling depths where its maximum value was obtained in the first two holes. With gas evolution not exceeding the permissible value, and the distance between the holes in the row, between the rows and from the drilled row of holes to the roof and soil of the mentioned bundle of angles, not exceeding the values determined by the radii of the effective influence of the hole according to the layering formation and cross layering, further drilling holes stop. 1 tab. / ate VS VS) ate

Description

The invention relates to the mining industry, in particular to the field of labor protection, and can be used in carrying out preparatory workings on. hazardous formations to prevent sudden release of coal and gas.

A known method of unloading rock mass from stresses. According to the known method, drill holes are drilled in the rock mass and form discharge slots in each of the drilled holes by applying a load distributed over the depth. A disadvantage of the known method is that. that it does not provide for gas release control during drilling of holes, is not technologically advanced and requires significant material costs and time for its implementation;

The closest technical solution is a method for controlling and preventing sudden emissions of coal and gas during coal mining

VI

layers. The known method includes drilling holes, determining the initial gas release rate, the critical value of the gas evolution rate, the drill hole output, setting the emission factor and the critical value of the emission hazard indicator, controlling the emission factor by comparing the obtained values of the emission hazard indicator with

critical.

The disadvantage of this method is that it is ineffective in preventing sudden releases, because It does not provide for control of the hazard in the process of drilling holes.

The aim of the invention is to increase the effectiveness of the prevention of sudden outbursts by maintaining emission control in the process of drilling chips

moat.

This goal is achieved in that in a method including drilling holes, determining an initial gas evolution rate, a critical gas evolution velocity, a drill hole exit, setting an emission hazard indicator and a critical emission hazard indicator, controlling the emission hazard by comparing the obtained emission index values c. critical, drilling holes is carried out on a potentially outburst coal seam pack and first drill two holes equidistant from the roof and soil of the seam on this pack, determine the outburst hazard of the seam from these 35 holes and the depth interval at which the maximum value of the gas evolution rate was obtained, and when the value of the emission factor was higher than the critical value in the site with previously drilled boreholes by 40: equal to the distance, a central borehole was drilled from them, then two additional boreholes were drilled to the same depth at equal then - between the central and extreme boreholes and in each of them during drilling 45 measure the initial velocity of gas evolution in the interval where its maximum value for the first two holes is obtained: and if the gas evolution is higher than acceptable in one; from bore holes t 50; next: traveling: a series of intermediate boreholes in the middle between drilled boreholes in a given row, and with gas evolution in the same interval, the depth of the borehole is not exceeded, -55

exceeding the critical value, and the following rows of holes are drilled without measuring gas evolution, moreover, the drilling of holes is completed if the distance between the holes in each row, starting from the second, is not 1. exceeds double radius

, -

5

10

fifteen

twenty

25 30 35 40 45 50.

55

effective influence on the layering equal to the obtained distance between the holes in the first row, and the distances from the critical rows to the roof and soil of the formation and between adjacent rows do not exceed, respectively, the radius of the effective influence of the hole across the layering, which is half its value on layering, and doubled radius of effective influence across the layering.

In accordance with the instructions for safe mining operations on the strata, the outburst hazard is predicted in the face of the preparatory mine for the initial gas release rate and the exit of the drill head from the control holes. However, in addition to the requirements of the known instructions, the following must be performed.

The control holes 1 must be equally removed from the soil and the roof of the potentially outburst coal pack, the holes are equally spaced from the soil and the roof of the outburst pack so that the destructive effect of the first series of holes on the upper and lower parts of the pack is the same, since the boreholes are USED simultaneously for emission hazard measures, and for unloading a coal pack From mountain and gas pressure.

If the outburst hazard of the bottomhole formation zone is already established during drilling of the first control borehole, it is necessary to drill the second control borehole and determine for it the interval values of the initial gas release rate. If at least one of the control boreholes yields a dangerous value of the outburst hazard indicator, tr, the bottom-hole part of the array is brought into a non-outburst state using the following technology.

A central hole is drilled between the forecast holes, equidistant from the first two to the same depth, i.e. 5.5 m. On thin and medium thicknesses and 6.5 m on thick formations. After that, two holes are drilled to the same depth between the central hole and the extreme holes, and in each of them, during drilling, the initial gas release rate of the days is measured in the interval where the maximum value for the forecast holes of this parameter is obtained. If you receive at least one of the last two holes, the value of 9 days 4 l / min-m drills the next series of intermediate holes in the middle between the drilled holes. If at least one length is received in the same interval

from holes the value of days another series of intermediate holes is drilled and day values are measured therein. in this interval. And so on, until at least one day value for a series of intermediate holes exceeds day cr. If not a single day in the series exceeds day cr, then the drilling of the holes in this series is completed. With a small power of a potentially outburst pack, when the distance from the drilled row of holes to the roof and the outburst pack does not exceed the radius of the effective influence of the borehole around the Ref.k. execution of the method is completed.: This radius is equal to half the radius of the effective influence on the stratification of Vef.n (i.e., one quarter of the obtained distance between adjacent holes D). At higher pack power, an additional number of drill holes is drilled between the drilled series and the roof and the soil of the formation, so that the distance between the 1 rows does not exceed 2REF. (i.e., D), and the distance from the roof and from the pack soil to the nearest row of holes would be no more. RZF.K. The number of holes in the additional rows should be such that the distance between them would be no more than 2REF. order, and the technologists of their drilling should be the same as in the first series. No gas emission measurements are made when drilling holes in additional rows.

The application of the proposed method is most advantageous when the potential of an outburst hazardous pack is small, when a large number of rows of holes are not drilled.

Example. A pilot test of the claimed method was carried out under the most unfavorable conditions on road. Yagunovsk when driving the main drift No. 702 on a potentially outburst-hazardous coal seam Lutuginsky. The drift bottom at the time of the experiment was in the zone of geological disturbance such as flexure. At the same time, it went beyond the formation. To go back to the formation, I had to open it in the violated zone. Opening a coal seam below a critical outburst depth, and also in a geological disturbance zone, is the most dangerous

an event from the position of initiating a sudden release. The method was applied during the opening of the formation and the subsequent main drift until the end of the disturbance zone.

The method parameters were as follows:

hole length 5.5 m; hole diameter 42 mm; minimum lead 1.5 m; reservoir thickness 3 m; angle of incidence 70 °.

During the first cycle, the holes were drilled through the rock plug, the distance from the bottom to the formation along the normal to the formation was 2.2 m. The forecast made during the drilling of the first two holes confirmed the assumed outburst hazard of the formation at the opening site. Further implementation of the proposed method was carried out according to the technology described above.

The table below shows where

for each full cycle of the method, the outlier of the zone according to the forecast for the first two holes, the maximum value of the initial gas release rate in days obtained in the intervals of these holes, the number of holes N, which was required to bring the zone to a non-hazardous state, the number of series (p dov) holes p and the maximum value of the initial velocity of gas evolution in

the last series of intermediate holes in days in the interval where it was measured

days.

As a result of the current hazard forecast made on 09/14/89, and

Further cycles of the current emission forecast. Non-hazardous values of the emission hazard index were obtained. They corresponded to the exit of the bottom from the disturbed zone.

The development was carried out using blasting in the mode of shattering blasting, which, as you know, are the most stringent test of effectiveness

blowout control measures.

The elimination of sudden outbursts when provoked by blasting after application of the proposed method for blow-out treatment of the bottom hole array indicates its high efficiency and practical use.

Claims (1)

SUMMARY OF THE INVENTION A method for controlling and preventing sudden outbursts of coal and gas during coal seam mining, including drilling holes, determining an initial gas evolution rate, a critical gas evolution rate, a drill hole exit, setting an emission hazard indicator, and ... a critical value of an emission hazard indicator, and monitoring the emission hazard by comparison obtained critical emission factor values, characterized in that, in order to increase the efficiency, In order to control sudden outbursts by monitoring the outburst hazard during drilling, the boreholes are drilled using a potentially outburst coal pack and, first, two boreholes are drilled from this bundle equidistant from the roof and soil of the formation, the outburst hazard of the formation is determined from these holes, the depth interval, at which the maximum value of the gas evolution rate was obtained, and when the value of the outburst hazard is higher than the critical value in the alignment with previously drilled boreholes, the central pur, then on the same the depth is drilled by two additional holes at an equal distance between the central extreme holes and in each of them during the drilling process the initial gas release rate is measured in the interval where its maximum value is obtained for the first two holes, and when the gas evolution value is higher than the permissible one at least one of the holes drilled the next series of intermediate holes in the middle between the drilled holes in this row, and when gas is released in the same interval of the depth of the hole, not exceeding the critical value, the following rows of holes are drilled t without measuring the gas release, moreover, the drilling of holes is completed if the distance between the holes in each row, starting from the second, does not exceed the value of the doubled radius of the effective influence on the layering equal to the obtained distance between the holes in the first row, and the distance from the extreme rows to the roof and the bed of the formation and between adjacent rows, respectively, does not exceed the radius of the effective influence of the cross hole layer, which is half its size in the layer, and the doubled radius of the effective influence across the layer.